Download Section 4.3 - math-clix

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Location arithmetic wikipedia , lookup

Theorem wikipedia , lookup

Chinese remainder theorem wikipedia , lookup

Proofs of Fermat's little theorem wikipedia , lookup

Horner's method wikipedia , lookup

System of polynomial equations wikipedia , lookup

Vincent's theorem wikipedia , lookup

Polynomial wikipedia , lookup

Factorization of polynomials over finite fields wikipedia , lookup

Fundamental theorem of algebra wikipedia , lookup

Transcript
Section 4.3
Polynomial Division;
The Remainder and
Factor Theorems
Copyright ©2013, 2009, 2006, 2001 Pearson Education, Inc.
Objectives

Perform long division with polynomials and
determine whether one polynomial is a factor of
another.
 Use synthetic division to divide a polynomial by
x  c.
 Use the remainder theorem to find a function value
f(c).
 Use the factor theorem to determine whether x  c is
a factor of f(x).
Division and Factors
When we divide one polynomial by another, we obtain a
quotient and a remainder. If the remainder is 0, then the
divisor is a factor of the dividend.
Example: Divide to determine whether x + 3 and
x  1 are factors of
3
2
x  2 x  5 x  4.
Example
Divide to determine whether x + 3 and x  1 are factors of
x 3  2 x 2  5 x  4.
x 2  5 x  20
x3
x3  2 x 2  5 x  4
x3  3x 2
5 x 2  5 x
5 x 2  15 x
20 x  4
20 x  60
64  remainder
Since the remainder is –64, we know that x + 3 is not a
factor.
Example (continued)
x2 
Divide:
x 1
x 4
x3  2 x 2  5 x  4
x3  x 2
 x2  5x
 x2  x
4x  4
4x  4
0  remainder
Since the remainder is 0, we know that x  1 is a factor.
Division of Polynomials
When dividing a polynomial P(x) by a divisor d(x), a
polynomial Q(x) is the quotient and a polynomial R(x) is
the remainder. The quotient must have degree less than
that of the dividend, P(x). The remainder must be either 0
or have degree less than that of the divisor.
P(x) = d(x) • Q(x) + R(x)
Dividend Divisor
Quotient Remainder
The Remainder Theorem
If a number c is substituted for x in a polynomial f(x),
then the result f(c) is the remainder that would be
obtained by dividing f(x) by x  c. That is, if
f(x) = (x  c) • Q(x) + R, then f(c) = R.
Example
Use synthetic division to find the quotient and remainder.
5
4
3
2

4
x

x

6
x

2
x
 50   ( x  2)

2 –4
Note: We must write a 0 for the
missing term.
1
6
2
0 50
–8 –14 –16 –28 –56
–4 –7 –8 –14 –28 –6
The quotient is – 4x4 – 7x3 – 8x2 – 14x – 28 and the
remainder is –6.
Example
Determine whether 4 is a zero of f(x), where
f(x) = x3  6x2 + 11x  6.
We use synthetic division and the remainder theorem to
find f(4).
4 1 –6 11 –6
4 –8 12
f (4)
1 –2 3 6
Since f(4)  0, the number 4 is not a zero of f(x).
The Factor Theorem
For a polynomial f(x), if f(c) = 0, then x  c is a factor of
f(x).
Example
Let f(x) = x3  7x + 6. Factor f(x) and solve the equation
f(x) = 0.
Solution: We look for linear factors of the form x  c.
Let’s try x  1:
1
1 0 –7
1
6
1 –6
1 1 –6
0
Example continued
Since f(1) = 0, we know that x  1 is one factor and the
quotient x2 + x  6 is another.
So,
f(x) = (x  1)(x + 3)(x  2).
For f(x) = 0, we have x =  3, 1, or 2.